Developing channel and floodplain dimensions with limited data: a case study in the Amazon Basin

被引:39
作者
Beighley, R. Edward [1 ]
Gummadi, Venkat [1 ]
机构
[1] San Diego State Univ, San Diego, CA 92182 USA
关键词
Amazon; bankfull; channel; floodplain; hydraulic geometry; HYDRAULIC-GEOMETRY; GRAPHICAL REPRESENTATION; RIVER; DISCHARGE; PATTERNS;
D O I
10.1002/esp.2132
中图分类号
P9 [自然地理学];
学科分类号
0705 ; 070501 ;
摘要
This research builds on the concept of hydraulic geometry and presents a methodology for estimating bankfull discharge and the hydraulic geometry coefficients and exponents for a station using limited data; only stage-discharge and Landsat imagery. The approach is implemented using 82 streamflow gauging locations in the Amazon Basin. Using the estimated values for the hydraulic geometry relations, bankfull discharge, discharge data above bankfull and upstream drainage area at each site, relationships for estimating channel and floodplain characteristics as a function of drainage area are developed. Specifically, this research provides relationships for estimating bankfull discharge, bankfull depth, bankfull width, and floodplain width as a function of upstream drainage area in the Amazon Basin intended for providing reasonable cross-section estimates for large scale hydraulic routing models. The derived relationships are also combined with a high resolution drainage network to develop relationships for estimating cumulative upstream channel lengths and surface areas as a function of the specified minimum channel width ranging from 2m to 1 km (i.e. threshold drainage areas ranging from 1 to 431,000 km(2)). At the finest resolution (i.e. all channels greater than 2m or a threshold area of 1 km(2)), the Amazon Basin contains approximately 4.4 million kilometers of channels with a combined surface area of 59,700 km(2). The intended use of these relationships is for partitioning total floodable area (channels versus lakes and floodplain lakes) obtained from remote sensing for biogeochemical applications (e.g. quantifying CO2 evasion in the Amazon Basin). Copyright (C) 2011 John Wiley & Sons, Ltd.
引用
收藏
页码:1059 / 1071
页数:13
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